20880-68-6Relevant academic research and scientific papers
Substrate promiscuity of the cyclic dipeptide prenyltransferases from Aspergillus fumigatus
Zou, Huixi,Zheng, Xiaodong,Li, Shu-Ming
, p. 44 - 52 (2009)
This study reports that a series of tryptophan derivatives with modifications on the side chain or at the indole ring were accepted by two cyclic dipeptide prenyltransferases, CdpNPT and FtmPT1, and converted to prenylated derivatives. The structures of t
Biochemical and Mechanistic Characterization of the Fungal Reverse N-1-Dimethylallyltryptophan Synthase DMATS1Ff
Burkhardt, Immo,Ye, Zhongfeng,Janevska, Slavica,Tudzynski, Bettina,Dickschat, Jeroen S.
, p. 2922 - 2931 (2019)
Dimethylallyltryptophan synthases catalyze the regiospecific transfer of (oligo)prenylpyrophosphates to aromatic substrates like tryptophan derivatives. These reactions are key steps in many biosynthetic pathways of fungal and bacterial secondary metabolites. In vitro investigations on recombinant DMATS1Ff from Fusarium fujikuroi identified the enzyme as the first selective reverse tryptophan-N-1 prenyltransferase of fungal origin. The enzyme was also able to catalyze the reverse N-geranylation of tryptophan. DMATS1Ff was shown to be phylogenetically related to fungal tyrosine O-prenyltransferases and fungal 7-DMATS. Like these enzymes, DMATS1Ff was able to convert tyrosine into its regularly O-prenylated derivative. Investigation of the binding sites of DMATS1Ff by homology modeling and comparison to the crystal structure of 4-DMATS FgaPT2 showed an almost identical site for DMAPP binding but different residues for tryptophan coordination. Several putative active site residues were verified by site directed mutagenesis of DMATS1Ff. Homology models of the phylogenetically related enzymes showed similar tryptophan binding residues, pointing to a unified substrate binding orientation of tryptophan and DMAPP, which is distinct from that in FgaPT2. Isotopic labeling experiments showed the reaction catalyzed by DMATS1Ff to be nonstereospecific. Based on these data, a detailed mechanism for DMATS1Ff catalysis is proposed.
Short, enantioselective total synthesis of okaramine N
Baran, Phil S.,Guerrero, Carlos A.,Corey
, p. 5628 - 5629 (2003)
The first enantioselective total synthesis of a member of the okaramine family of bis-indole alkaloids, okaramine N (1), has been accomplished via intermediates 2-7, as outlined. The N-prenylated derivative of (S)-tryptophan methyl ester (2) was coupled with Fmoc-protected N-tert-prenylated tryptophan (3) to form the amide 4 in 70% yield. Pd(II)-mediated cyclization/rearrangement, a key step in the synthesis, transformed 4 into the indoloazacine 5 (44%), which was deprotected and cyclized in a single step to give the hexacyclic diketopiperazine 6 (95%). In the following novel and key sequence, 6 was transformed into 1: (1) selective ene reaction with N-methyltriazolinedione, (2) photooxidation of the remaining tert-prenylated indole subunit to provide 7, and (3) thermal retroene reaction of 7 to afford okaramine N (70% from 6). Copyright
Functional characterization of the cyclomarin/cyclomarazine prenyltransferase cymd directs the biosynthesis of unnatural cyclic peptides
Schultz, Andrew W.,Lewis, Chad A.,Luzung, Michael R.,Baran, Phil S.,Moore, Bradley S.
, p. 373 - 377 (2010)
In vitro and in vivo characterization of the cyclomarin/cyclomarazine prenyltransferase CymD revea].ed its ability to prenylate tryptophan prior to incorporation into both cyclic peptides by the nonribosomal peptide synthetase CymA. This knowledge was utilized to bioengineer novel derivatives of these marine bacterial, natural products by providing synthetic N-alkyl tryptophans to a prenyltransferase-deficient mutant of Salinispora arenicola CNS-205.
Tyrosine O -prenyltransferase SirD catalyzes S -, C -, and N -prenylations on tyrosine and tryptophan derivatives
Rudolf, Jeffrey D.,Poulter, C. Dale
, p. 2707 - 2714 (2014/01/06)
The tyrosine O-prenyltransferase SirD in Leptosphaeria maculans catalyzes normal prenylation of the hydroxyl group in tyrosine as the first committed step in the biosynthesis of the phytotoxin sirodesmin PL. SirD also catalyzes normal N-prenylation of 4-aminophenylalanine and normal C-prenylation at C7 of tryptophan. In this study, we found that 4-mercaptophenylalanine and several derivatives of tryptophan are also substrates for prenylation by dimethylallyl diphosphate. Incubation of SirD with 4-mercaptophenylalanine gave normal S-prenylated mercaptophenylalanine. We found that incubation of the enzyme with tryptophan gave reverse prenylation at N1 in addition to the previously reported normal prenylation at C7. 4-Methyltryptophan also gave normal prenylation at C7 and reverse prenylation at N1, whereas 4-methoxytryptophan gave normal and reverse prenylation at C7, and 7-methyltryptophan gave normal prenylation at C6 and reverse prenylation at N1. The ability of SirD to prenylate at three different sites on the indole nucleus, with normal and reverse prenylation at one of the sites, is similar to behavior seen for dimethylallyltryptophan synthase. The multiple products produced by SirD suggests it and dimethylallyltryptophan synthase use a dissociative electrophilic mechanism for alkylation of amino acid substrates.
